Uncertainty in East Antarctic firn thickness constrained using a model ensemble approach

Verjans, Vincent; Leeson, Amber; McMillan, Malcolm; Stevens, Max; Wessem, Jan Melchior van; Berg, Willem Jan van de; Broeke, Michiel van den; Kittel, Christoph; Amory, Charles; Fettweis, Xavier; Hansen, Nicolaj; Boberg, Fredrik; Mottram, Ruth

doi:10.5194/egusphere-egu21-140

Cited by 1 publication

(1 citation statement)

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“…The compaction profile of the firn column therefore preserves the local climate history, recording the amount of snow accumulation, snow melt, temperature conditions and the subsequent preservation of the snow. Firn also represents an important factor of uncertainty for estimating changes of surface mass balance (Verjans et al, 2021;Kowalewski et al, 2021), where the current rate of change of ice sheets' mass balance is often derived from tracking changes in surface elevation from satellite altimetry or interferometry.…”

Section: Introductionmentioning

confidence: 99%

Firn Seismic Anisotropy in the North East Greenland Ice Stream from Ambient Noise Surface Waves

Pearce,

Zigone,

Hofstede

et al. 2023

Preprint

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Abstract. We analyse ambient noise seismic data from 23 three-component seismic nodes to study firn velocity structure and seismic anisotropy near the EastGRIP camp along the Northeast Greenland Ice Stream (NEGIS). Using 9-component correlation tensors, we derive dispersion curves of Rayleigh and Love wave group velocities from 3 Hz to 40 Hz. These velocity distributions exhibit anisotropy along and across the flow. To assess these variations, we invert dispersion curves for shear wave velocities (Vsh and Vsv) in the top 150 m of NEGIS using a Markov Chain Monte Carlo approach. The reconstructed1-D shear velocity model reveals radial anisotropy in the firn, with Vsh 12 %–15 % greater than Vsv, peaking at the critical density (550 kg m–3). We combine density data from firn cores drilled in 2016 and 2018 to create a new density parameterisation for NEGIS, serving as a reference for our results. We link seismic anisotropy in the NEGIS to effective and intrinsic causes. Seasonal densification, wind crusts, and melt layers induce effective anisotropy, leading to faster Vsh waves. Changes in firn recrystalisation cause intrinsic anisotropy, altering the Vsv to Vsh ratio. We observe a shallower firn-ice transition across flow (≈ 50 m) compared to along flow (≈ 60 m), suggesting increased firn compaction due to the predominant wind direction and increased deformation towards the shear margin. We demonstrate that short-duration (nine-day minimum), passive, seismic deployments, and noise-based analysis can determine seismic anisotropy in firn, and reveal 2-D firn structure and variability.

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Section: Introductionmentioning

confidence: 99%